NGC 2110 Spectroscopy Dan Evans (Harvard), Julia Lee (Harvard), Jane Turner (UMBC/GSFC), Kim Weaver (GSFC), Herman Marshall (MIT)
NGC 2110 Spectroscopy The Fe Kα line complex in general consists of a narrow line core, possibly accompanied by broadened emission What is the origin of the broad emission? Relativistically blurred diskline? Compton shoulder? Broad line region? Unmodeled absorption? If we can deconvolve the contributions from the two, we can probe AGN geometry Vital to treat direct+reflected continuum and absorption effects self-consistently Fe Kα Lines and Reflection: AGN Geometry NGC 3783 (Yaqoob et al. 2005)
NGC 2110 Spectroscopy Nearby (z=0.0076, D L =33 Mpc) NELG Historical subclass of Seyferts with narrow (<600 km/s) optical lines (Sy 2-like) but much stronger hard X-ray emission (Sy 1-like) Flat X-ray spectra may imply they dominate XRB at low energies (e.g. Iwasawa et al. 1997) Transitional between Sy 1 and Sy 2? (Lawrence & Elvis 1982) ASCA, BeppoSAX, etc. 2-10 keV X-ray spectrum is very flat (Г=1.4) Accompanied by moderate absorption (N H =3x10 22 cm -2 ) ASCA Fe K complex hard to interpret Diskline, either oriented at intermediate angles to l.o.s. (Weaver & Reynolds 1998) or nearly face-on (Turner et al. 1998) NGC 2110
NGC 2110 Spectroscopy
Chandra and XMM-Newton NGC 2110 was observed with Chandra for a total of 250 ks and XMM-Newton for 60 ks. An initial analysis showed variability in flux only, and so the continuum spectra were analyzed jointly. HETGS light curve 2001 Dec2003 Mar
NGC 2110 Spectroscopy Initial fit with single, moderately absorbed power law (N H =3x10 22 cm - 2, Г=1.4) Soft excess seen below 2 keV Significant improvement in fit with the addition of a lightly absorbed (N H =7x10 20 cm -2 ) power law (Г soft =Г hard ) Still very flat photon index (Г=1.4), but… Continuum Fitting XMM pn MEG XMM pn MEG
NGC 2110 Spectroscopy Insufficient opacity at Si K and Fe K edges Improvement in the fit with the additional edges Does this imply an extra absorber? Significant improvement with a 3x partially covered power law Photon index rises to Г=1.74±0.05 consistent with canonical values in Seyferts No evidence for ionized absorption in HETGS data Continuum Fitting HEG XMM pn MEG HEG
NGC 2110 Spectroscopy Fluorescent Line Diagnostics Chandra HETGS best suited to probe narrow lines Neutral fluorescent Kα lines detected from Si, S, Ar, Ca, Fe Narrow Fe Kα and Si Kα line cores just resolved with HETGS Distant, neutral fluorescing region No evidence for diskline Marginal (2.5σ) evidence for v. slight broadened base of Fe Kα HEG
NGC 2110 SpectroscopyReflection Self-consistent treatment of reflection (i.e., lines+pexrav continuum) No change in fit parameters Suzaku provides vital constraints on strength of reflection Stringent limit of R<0.1 (Reeves et al. 2006; Okajima et al. 2007) NGC 2110 is one of the few Seyferts with no evidence for disk reflection, nor complex absorption Suzaku – NGC 2110 (Reeves et al. 2006)
NGC 2110 Spectroscopy
Multiwavelength Imaging Excellent spatial agreement between X-ray and [OIII] (Evans et al. 2006) Both clearly offset from radio, but extend along similar p.a. X-ray & [OIII] emission influenced by, but not directly associated with, radio jet? ACIS X-ray spectrum modeled by, e.g., two thermal plasma models (kT 1 =0.3 keV; kT 2 =5 keV) Chandra ( keV) / VLA / HST [OIII] 2’’=320 pc
NGC 2110 Spectroscopy Gratings Spectrum Tentative evidence for O VIII Ly α, as well as the O VIII RRC feature first reported by Guainazzi & Bianchi (2006) High-resolution grating spectroscopy can in principle distinguish between these models Evans et al. (2006) considered 3 mechanisms for producing the environment: Shock-heating by the radio jet Electron-scattered nuclear radiation Photoionization by the AGN Photoionization and collisional ionization processes both important?
NGC 2110 Spectroscopy
Recap ASCA, BeppoSAX, etc. found Flat (Г=1.4) 2-10 keV spectrum Moderate absorption (N H =3x10 22 cm -2 ) Diskline emission, either face-on or at intermediate angles Chandra, XMM-Newton (and Suzaku – Okajima et al. 2007) Compton-thin partial-coverer model Photon index No evidence for ionized absorption Marginally resolved (900±500 km s -1 ) Fe Kα line core No evidence for disk reflection Multiwavelength imaging + HETGS evidence for (weak) ionized emission extended circumnuclear environment is photoionized or collisionally ionized? 2’’=320 pc
NGC 2110 Spectroscopy Consistent with an origin in a Compton-thin, distant (> 1pc) neutral absorber Orientation consistent with edge-on view Steepening of photon index using multiple partial-coverer model NELGs do not have significantly flatter spectra w.r.t. Seyfert 1, 2? No disk reflection, unlike other Compton-thin Seyferts observed with Suzaku (Reeves et al. 2006) Vital to treat absorption and reflection effects in a self-consistent manner in order to evaluate AGN geometry High spatial and spectral resolution, together with high effective area, are key to determining the spatial distribution and energetics (collisional vs. photoionization) of circumnuclear environments in AGN